DE902632C - Transformer for generating a high DC voltage from saw tooth currents - Google Patents

Description

The patent 7281212 describes a high voltage transformer described, which has two or more high-voltage windings, to each one Rectifier tube is connected and in which the self-capacitance of the winding is thereby reduced to one The smallest possible value has been brought so that the individual high-voltage windings are arranged be that points of the same alternating potential are adjacent. According to one there The embodiment shown are in the case of a transformer core with a horizontal winding window two or more high voltage windings in

Form of solenoids wound next to each other with an interlayer of insulating layer.

In contrast, the invention relates to a more expedient winding arrangement which allows the capacity of the individual partial windings and, through appropriate distribution in groups of windings, the stress between the To reduce part windings arranged insulating layers even further. The various high voltage windings are subdivided into several sub-coils and the sub-coils become winding groups summarized that sub-coils that

belong to different high-voltage windings, are arranged within a group in such a way that that points: the same alternating potential are adjacent and adjacent partial coils are adjacent Winding groups belong to the same high-voltage winding and are adjacent within this are.

The invention is explained in more detail by the drawing.

ίο Fig. ι shows a high-voltage transformer in schematic form with the winding arrangement according to the invention and

2 shows a corresponding circuit example for this; Figs. 3 and 4 illustrate another embodiment represent.

In Fig. Ι 1 represents the ferromagnetic core of a transformer with longitudinal winding windows 2 on which those indicated in FIG Partial coils of the high-voltage winding

genes 3, 4, 5 are arranged. According to the present example, the high-voltage windings 3, 4, 5 are each in four sub-coils 3 ⁰ to. 3 ^d , 4 ^a to 4 ^d and 5 ^a to ¹ $ ^d and each of the sub-coils 3 °, 4 °, 5 ⁰ or 3 ⁶ , 4 ^Ö , 5 ⁶ etc. to the

Groups 7, 8, 9, 10 combined. The order the sub-coils within the groups is made according to the invention so that the sequence is reversed in neighboring groups, i.e. according to the scheme:

Group 7 8 9

10

Partial coils 3 ⁰ , 4 ⁰ , 5 ⁰ , 5 ⁶ > 4 ^b > 3 ^b > 3 ^C > 4 ^C > 5 ^C - 5 ^d · 4 ^d - 3 ^d

As can be seen from Fig. 1, the partial

spufen within the winding groups according to the

Patent 72: 8 122 arranged so that points are alike Alternating potential are adjacent. The winding type of all sub-coils is the same, so that in the areas of the individual partial windings close to the core, for example ο volts, in the middle 500 volts and in

the areas close to the jacket at the upper edge of the windings in all sub-coils of a winding group z. B. 1000 volts are available. It rules thus no harmful transhipment capacity.

Due to the spatial separation of the various partial windings belonging to a high-voltage winding there is also a substantial reduction in the total capacity of the transformer winding achieved. A low capacity is desirable because, on the other hand, when it is increased by Too large a capacity the time constant of the arrangement is increased and thus the amplitude of the obtained high voltage drops,

It should also be noted that between the individual Parts of the winding arrangement do not

There is a casually high DC voltage difference. In this sense it is essential that in the end one Coil group and are arranged at the beginning of the next sub-coils, which belong to a high-voltage winding and are within the same

are neighbors. For example, in FIG. 1, the last coil section of the first group of turns, S ^{a , is followed by a coil section 5 6} belonging to the same high-voltage winding, namely winding 5, “which follows coil 5 within high-voltage winding 5”.

For example, if one were to follow coil 3 ^& as the starting coil of the next group of turns on sub-coil 5 ", the full DC voltage would be effective between the two groups, so that high demands would have to be made on the insulation between them. For example, it would be necessary between To arrange two coil groups high-quality insulation material, which would again lead to an increase in capacitance. By reducing the DC voltage difference between two adjacent winding groups, it is possible to dispense with insulation material between the individual groups; in this case, air is sufficient as the insulation medium.

The winding arrangement according to the invention ensures that the total capacitance of a transformer constructed according to this type of η groups with ρ coils each is not greater than that of one with high dielectric strength between the individual coils. η iSchaibenspulen built air-insulated transformer, while the high voltage generated is /> times greater than that of a simple transformer with disk coils. Such an arrangement makes it possible to accommodate a large number of coils in a group and thus to increase the high voltage generated according to FIGS. 2 and 3 as desired without the inherent capacitance of the transformer increasing significantly.

2 and 3 show two schematic circuit examples, transformers according to FIG. 1 are used for their implementation.

In Fig. 2, 11 is a tilting amplifier tube, the grid of which is supplied with a pulse voltage and in the anode coil 3 of which a sawtooth current flows. The coil 3 is located with the high-voltage windings 4 and 5 on the transformer 1. The high voltages generated in the coils 3, 4, 5 by the return voltage peaks are then rectified by the rectifiers xz, 13, 14 and the DC voltages connected in series at the terminals 15 and 16 removed. Filter capacitors 17, 18, 19 are also arranged between the individual stages. The heating for the rectifiers 12, 13, 14 is taken directly from the transformer ι by additional windings 20, 21 22.

Fig. 3 shows a further application example for a transformer feedback circuit for simultaneous generation of deflection currents and high voltage for the cathode ray tube in which the tube 23 is the tilting tube, its anode coil 3 and its grid coil 24 together with the further high-voltage windings 4, 5, 6 are arranged on the iao transformer 1; 27 represents the capacitively coupled deflection coils. The coil arrangement on the transformer core is expediently selected according to FIG. The heating for the rectifier tubes is not using additional Generated coils, but directly a part

winding taken from the high-voltage winding following the coil in question. Just for them Last rectifier tube, an additional winding 26 must be arranged. The terminals 15 and 16 the rectified high voltage is taken. The individual filter capacitors are replaced by a single capacitor 25 in this example. In contrast to FIG. 2 are in Fig. 3, the high-voltage windings divided into six sub-coils. It has been found to be functional proved to be the division of the high-voltage winding into an even number of sub-coils to undertake. From Fig. 4 it can also be seen that the grid coil 24 of the tilt generator tube 23 in the middle is arranged between the six groups. This is advantageous because it allows the The scatter between the anode and the grid winding becomes small, d. H. but the coupling is desirable is great.

In order to be able to save on insulating material between the high-voltage windings and the transformer core, the core of the transformer has a potential difference with respect to the coils which corresponds to part of the high voltage occurring overall on the high-voltage windings. If air is used as insulation between the coils and the core for all sub-coils, the core will expediently be placed at approximately half the DC high voltage, so that only half the flashover safety needs ^{to be applied between the core and the coils 1.} If partial coils are insulated from the core in a high-voltage-safe manner by insulating material, the core can also be connected to another part of the high-voltage DC. In order to save on winding space and insulating material, the coil section of the high-voltage winding 4, which is directly connected to the transformer core, as indicated in FIG. 3, is arranged adjacent to the core. The distance can be made small, since there are no DC voltage differences between the two. Furthermore, it is expedient to make the arrangement so that, as can be seen from FIG. 4, partial coils of the anode winding 3 of the tilt generator tube are in the vicinity of the grid coil 24, because there is no high DC voltage between them either.

(The coil arrangement according to the invention is particularly advantageous at higher frequencies and is particularly suitable for generating high voltage from breakover currents in televisions, it does not matter whether the transformer is arranged behind an amplifier tube or is used directly as a tilting transformer.

Claims (3)

Patent claims: i. Transformer for generating a high DC voltage from sawtooth currents with the help two or more high-voltage windings, to each of which a rectifier tube is connected is, according to patent 728 122, characterized in that each of the high voltage windings is divided into several sub-coils and the sub-coils are thus combined into winding groups are that sub-coils that belong to different high-voltage windings, are arranged within a group in such a way that points of the same alternating potential are adjacent and adjacent sub-coils of adjacent winding groups of the same high-voltage winding belong and are adjacent within this. 2. Transformer according to claim 1, characterized in that the transformer core with respect to the coils a potential difference in terms of direct voltage, which is a part of the total corresponding high voltage occurring. 3. Transformer according to claim 1, characterized in that the connected to the core Part of the coil is adjacent to the core. 1 sheet of drawings © 5703 1.54